(a)Use the Bohr model to determine the ionization energy of the `He^+` ion, which has a single electron. (b)Also calculate the maximum wavelength a photon can have to cause ionization.

Determine the minimum wavelength of a photon the can cause ionization of He ^(+) ion.

Calculate the wavelength of a photon in Angstroms having an energy of 1 electron-volt.

The work function of the metal A is equal to the ionization energy of the hydrogen atom in the first excited state. The work function of the metal B is equal to the ionization energy of He^+ ion in the second orbit. Photons of the same energy E are incident on both A and B the maximum kinetic energy of photoelectrons emitted from A is twice that of photoelectrons emitted from B. Value of E (in eV) is

(a) Using the Bohr's model, calculate the speed of the electron in a hydrogen atom in the n=1,2 and 3 levels. (b) Calculate the orbital period in each of these levels.

With the help of Bohr 's model , calculate the second ionisation energy of helium (energy required to remove the electron from He^(o+)

When an atom X absorbs radiation with a photon energy than the ionization energy of the atom, the atom is ionized to generate an ion X^(+) and the electron (called a photoelectron) is ejected at the same time. In this event, the energy is conserved as shown in Figure 1 , that is, Photon energy (h)=ionization energy (IE) of X+ kinetic energy of photoelectron. When a molecule, for example, H_(2) , absorbs short-wavelength light, the photoelectron is ejected and an H_(2) , ion with a variety of vibrational states is produced. A photoelectron spectrum is a plot of the number of photoelectrons as a function of the kinetic energy of the photoelectrons. Figure-2 shows a typical photoelectron spectrum when H_(2) in the lowest vibrational level is irradiated by monochromatic light of 21.2 eV . No photoelectrons are detected above 6.0 eV . (eV is a unit of energy and 1.0 eV is equal to 1.6xx10^(-19) J ) Figure 1 Schematic diagram of photoelectron spectroscopy. Figure 2 Photoelectron spectrum of H_(2) . The energy of the incident light is 21.2 eV Considering an energy cycle, ul("determine") the bond energy E_(D)( eV) of H_(2)^(+) to the first decimal place. If you were unable to determine the values for E_(B) and E_(C) , then use 15.0 eV and 5.0 eV for E_(B) and E_(C) , respectively.

A photon and an electron have the same de Broglie wavelength. Which has greater total energy? Explain

If out of two given elements A and B, A has a higher ionization energy than B, which element is expected to be more electronegative A or B ?

A certain species of ionized atoms produces emission line spectral accorduing to the Bohr's model. A group of lines in the spectrum is forming a series in which in the shortest wavelength is 22.79 nm and the longest wavelength is 41.02 nm . The atomic number of atom is Z . Based on above information, answer the following question: The series belongs to

Determine the degree if ionization and pH of 0.05 M of ammonia solution. The ionization constant of ammonia can be taken from Table 7.7. Also calculate the ionization constant of the conjugate acid of ammonia.